Bulk viscous matter in f(T) gravity: A path to cosmic acceleration

Abstract

In this paper, we investigate the effects of varying bulk viscosity coefficients ζ(t)=ζ0+ζ1H on cosmic evolution within the framework of f(T) teleparallel gravity. We focus on two cases: (i) ζ1 ≠0 and (ii) ζ1 =0, deriving the Hubble parameter H as a function of redshift z using a linear f(T) model (f(T) = α T where α ≠ 0). Using the combined H(z)+Pantheon++BAO dataset, we obtain observational constraints on model parameters. For Case I (ζ1 ≠ 0), best-fit values are H0=60.0+2.0-1.9 km/s/Mpc, α=1.01+0.10-0.098, ζ0=40.1+1.9-2.0, and ζ1=0.123+0.093-0.088, while for Case II (ζ1 = 0), they are H0=67.5+1.3-1.3 km/s/Mpc, α=0.94+0.14-0.13, and ζ0=34.7+2.0-2.0. The analysis reveals a transition in the deceleration parameter, indicating a shift from deceleration to acceleration of the universe's expansion, with present-day values of q0 ≈ -0.49 and q0 ≈ -0.32 for the respective cases. The jerk parameter j(z) and effective EoS for the cosmic viscous fluid also support the cosmic acceleration, with trajectories aligning with the quintessence scenario. These findings underscore the potential of our f(T) model dominated by bulk viscous matter in explaining cosmic acceleration.